清脆的
转座酶
Cas9
生物
转座因子
基因组编辑
计算生物学
遗传学
基因组工程
基因靶向
基因
人口
基因组
医学
环境卫生
作者
Mahere Rezazade Bazaz,Mohammad Mahdi Ghahramani Seno,Hesam Dehghani
标识
DOI:10.1038/s41598-022-07158-8
摘要
Abstract Various methods have been used in targeted gene knock-in applications. CRISPR-based knock-in strategies based on homology-independent repair pathways such as CRISPR HITI have been shown to possess the best efficiency for gene knock-in in mammalian cells. However, these methods suffer from the probability of plasmid backbone insertion at the target site. On the other hand, studies trying to combine the targeting ability of the Cas9 molecule and the excision/integration capacity of the PB transposase have shown random integrations. In this study, we introduce a new homology-independent knock-in strategy, Transposase-CRISPR mediated Targeted Integration (TransCRISTI), that exploits a fusion of Cas9 nuclease and a double mutant piggyBac transposase. In isogenic mammalian cell lines, we show that the TransCRISTI method demonstrates higher efficiency (72%) for site-specific insertions than the CRISPR HITI (44%) strategy. Application of the TransCRISTI method resulted in site-directed integration in 4.13% and 3.69% of the initially transfected population in the human AAVS1and PML loci, respectively, while the CRISPR HITI strategy resulted in site-directed integration in the PML locus in only 0.6% of cells. We also observed lower off-target and random insertions in the TransCRISTI group than the CRISPR HITI group. The TransCRISTI technology represents a great potential for the accurate and high-efficiency knock-in of the desired transposable elements into the predetermined genomic locations.
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